The NIH Mentored Clinical Scientist Research Career Development Award (K08) proposal describes a five- year training program for career development in academic pulmonary medicine. The principal investigator, William Oldham, M.D., Ph.D., is an Associate Physician and Instructor of Medicine in the Division of Pulmonary and Critical Care Medicine at the Brigham and Women's Hospital (BWH) and Harvard Medical School. He has a background in chemistry and biochemistry and completed doctoral research in pharmacology while a member of the NIH Medical Scientist Training Program at Vanderbilt University. He completed clinical training in Internal Medicine, Pulmonary Disease, and Critical Care Medicine in 2012. His goal is to develop a successful career as an independently funded physician-scientist investigating redox metabolism in pulmonary vascular disease. With the support and protected time provided by the K08 award, Dr. Oldham will develop expertise in the fields of energy metabolism, redox biochemistry, mitochondrial physiology, and dynamic modeling from formal coursework, independent study, and practical experience with relevant experimental techniques. Dr. Joseph Loscalzo, an internationally recognized expert in these areas with over 30 years of mentoring experience, will mentor Dr. Oldham with the support of an advisory committee composed of outstanding scientists in metabolism and pulmonary disease. As the award period progresses, Dr. Oldham will develop the skills necessary for a successful R01 grant submission. Dr. Oldham will work in the Division of Pulmonary and Critical Care Medicine in the Department of Medicine at BWH, an outstanding scientific and mentoring environment located within the heart of the Harvard Medical School community. Pulmonary arterial hypertension affects 15-50 people per million and elevated pulmonary artery pressures con- tribute to increased morbidity and mortality of millions more affected by lung disease, heart failure, and other conditions. Metabolic abnormalities in PAH offer a rich potential for the development of much-needed disease modifying therapies for this condition. Dr. Oldham's long-term goal is to define the metabolic derangements underlying PAH and to develop therapies targeting the resulting metabolic vulnerabilities. The overall objective of this application is to define the role of L2HG in the pathogenesis of PAH as the first step toward his long- term goal. The central hypothesis is that L2HG production supports pulmonary vascular remodeling in PAH by increasing pro-proliferative reactive oxygen species generation in pulmonary vascular cells. The rationale for this proposal is that, once the links between L2HG metabolism and PAH pathogenesis are defined, these bio- chemical pathways can be targeted pharmacologically, resulting in novel and disease-modifying therapies for PAH. The central hypothesis will be tested by pursuing the following specific aims: (1) Determine the biochemical link between L2HG metabolism, glycolysis, and cellular redox state using biochemical and kinetic modeling approaches; (2) Determine the impact of L2HG metabolism on pulmonary vascular cell phenotype using genetic manipulations of L2HG levels and readouts of cell proliferation, apoptosis, and reactive oxygen species production; and (3) Determine the role of L2HG metabolism in the development of PAH using genetically modified mice. The contribution of this work is expected to be a mechanistic understanding of how L2HG metabolism regulates cellular redox homeostasis in support of pulmonary vascular remodeling in PAH. This contribution will be significant because it will define a critical role for L2HG in normal and diseased metabolism that will enhance our understanding of the cellular response to hypoxia and other stressors. The proposed research is innovative because it represents a new and substantive departure from the status quo by defining an important role for L2HG metabolism in cellular redox homeostasis. This research will open new horizons in the study of intracellular redox signaling. Moreover, this pathway has not been previously associated with PAH and represents a new area for mechanistic investigations of disease pathogenesis. Since L2HG is not an intermediate in any known metabolic pathway, its metabolism may offer safe and tractable experimental and therapeutic tar- gets for manipulating cellular redox state, which would provide a valuable tool for future investigations of this deadly disease.

Public Health Relevance

Increased blood pressure in the lungs (pulmonary hypertension) is caused by narrowing of the pulmonary blood vessels by abnormal vessel cell growth. Accumulating research suggests abnormal metabolism contributes to cell proliferation, and we have identified one metabolite, L-2-hydroxyglutarate (L2HG), whose concentrations increase in cell culture models of and patients with pulmonary hypertension. We propose to study the role of L2HG metabolism in the development of pulmonary hypertension.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Clinical Investigator Award (CIA) (K08)
Project #
5K08HL128802-02
Application #
9240659
Study Section
Special Emphasis Panel (MCBS (JA))
Program Officer
Colombini-Hatch, Sandra
Project Start
2016-04-01
Project End
2021-03-31
Budget Start
2017-04-01
Budget End
2018-03-31
Support Year
2
Fiscal Year
2017
Total Cost
$172,400
Indirect Cost
$12,400
Name
Brigham and Women's Hospital
Department
Type
Independent Hospitals
DUNS #
030811269
City
Boston
State
MA
Country
United States
Zip Code
02115
Samokhin, Andriy O; Stephens, Thomas; Wertheim, Bradley M et al. (2018) NEDD9 targets COL3A1 to promote endothelial fibrosis and pulmonary arterial hypertension. Sci Transl Med 10:
Oldham, William M; Oliveira, Rudolf K F; Wang, Rui-Sheng et al. (2018) Network Analysis to Risk Stratify Patients With Exercise Intolerance. Circ Res 122:864-876
Bertero, Thomas; Oldham, William M; Grasset, Eloise M et al. (2018) Tumor-Stroma Mechanics Coordinate Amino Acid Availability to Sustain Tumor Growth and Malignancy. Cell Metab :
Kim, Edy Yong; Oldham, William M (2018) Innate T cells in the intensive care unit. Mol Immunol 105:213-223
Yang, Jia-Shu; Hsu, Jia-Wei; Park, Seung-Yeol et al. (2018) GAPDH inhibits intracellular pathways during starvation for cellular energy homeostasis. Nature 561:263-267
Fessel, Joshua P; Oldham, William M (2018) Nicotine Adenine Dinucleotides: The Redox Currency of the Cell. Antioxid Redox Signal 28:165-166
Fessel, Joshua P; Oldham, William M (2018) Pyridine Dinucleotides from Molecules to Man. Antioxid Redox Signal 28:180-212
Wang, Rui-Sheng; Oldham, William M; Maron, Bradley A et al. (2018) Systems Biology Approaches to Redox Metabolism in Stress and Disease States. Antioxid Redox Signal 29:953-972
Lam, Hilaire C; Baglini, Christian V; Lope, Alicia Llorente et al. (2017) p62/SQSTM1 Cooperates with Hyperactive mTORC1 to Regulate Glutathione Production, Maintain Mitochondrial Integrity, and Promote Tumorigenesis. Cancer Res 77:3255-3267
Lam, Hilaire C; Liu, Heng-Jia; Baglini, Christian V et al. (2017) Rapamycin-induced miR-21 promotes mitochondrial homeostasis and adaptation in mTORC1 activated cells. Oncotarget 8:64714-64727

Showing the most recent 10 out of 11 publications